KR100676553B1 - Dielectric barrier discharge lamp and method and circuit for igniting and operating said lamp - Google Patents

Abstract

The present invention relates to a long electrode of a dielectric barrier discharge lamp which is divided into two partial electrodes (A, A ') by a gap (L). The two partial electrodes A, A 'ignite the auxiliary discharge in the region of the electrode gap L in the ignition step, which facilitates ignition of the main discharge E, especially when the lamp is off. Controlled in such a way. In normal operation the partial electrodes A, A 'are controlled in a suitable manner to generate a main discharge E.

Description

Dielectric barrier discharge lamps, and methods and circuits for igniting and operating the lamps TECHNICAL FIELD             

(Technology)
The present invention relates to a dielectric barrier discharge lamp, a method for igniting and operating the lamp, and a circuit suitable for implementing the method.

(Background)
Dielectric barrier discharge lamps are electromagnetic radiation sources based on dielectrically disturbed gas discharges.

Dielectric barrier discharge lamps have at least one so-called dielectrically disturbed electrode as a prerequisite. The dielectrically disturbed electrode is separated from inside the discharge vessel by a dielectric barrier. This dielectric barrier is formed, for example, as a dielectric layer covering the electrode, or by the discharge tube itself of the lamp when the electrode is disposed on the outer wall of the discharge tube.

Due to the dielectric barrier a time varying voltage between the electrodes is required for the operation of the lamp of this type, for example a sinusoidal alternating voltage or pulse voltage as known from US-A 5 604 410.

The shape of the discharge tube is arbitrary in principle. For example tubular or planar. In particular the invention relates to so-called flat lamps and tubular lamps with or without openings.

In the case of a planar lamp, the discharge vessel is formed by a base plate and a front plate connected to the base plate. Light emission is typically achieved by the front plate. Flat lamps are particularly suitable for direct backlighting of displays such as large area illumination, for example liquid crystal displays, but may also be suitable for general illumination.

In the case of the tubular lamp, the discharge tube is formed into a tube, and the tube is sealed at both ends. Light emission is either through the front surface of the discharge tube or only through the long opening (opening lamp). Aperture lamps are particularly suitable for office automation (OA) devices such as color copiers and color scanners, signal lights such as brake lights and turn signals for automobiles, auxiliary lights such as car interior lights and so-called "edge type backlights". It is used for background lighting of a display such as an LCD screen.

The discharge tube is usually filled with an inert gas or gas mixture such as xenon. A so-called excimer is formed during gas discharge which is preferably operated by the pulse operation method known from US-A 5 604 410. Excimer is the molecule, such as Xe ₂ ^* Here, the Xe ₂ ^* is emitting electromagnetic radiation, usually, when returning to the non-coupled base state. In the case of Xe ₂ ^* , the maximum molecular band radiation is about 172 nm (VUV radiation).

In US-A 6 034 470 a flat lamp having a dielectrically disturbed electrode is known. The discharge tube of the lamp consists of a base plate and a front plate, and the two plates are connected to each other in an airtight manner through a peripheral frame. The base plate has one light reflection layer. In other words, only the front plate is used for light emission. The inner walls of the base plate and the front plate are coated with a phosphor layer (see Figure 6b). This achieves high luminous efficiency and / or high luminance in the front plate. Of course, long-lasting ignition delays after voltage is applied to the lamp electrodes are disadvantageous when the lamp is not visible, for example when present inside the LCD display. In the invisible case, after a long time, the lamp may only be ignited by a much higher voltage than in normal operation.

In US Pat. No. 5,006,758 a planar lamp with a dielectrically disturbed pair of electrodes is known, which pair is connected in pairs to both poles of a high voltage source. The electrode consists of a wire and is inserted into a planar glass dielectric. In operation, creeping discharges are formed on the dielectric surface between each adjacent electrode wire. On the dielectric surface a coating is provided to reduce the ignition voltage for discharge. The coating material includes magnesium, ytterbium, lanthanum and oxides such as cerium (MgO, Yb ₂ O ₃ , La ₂ O ₃ , CeO ₂ ). A phosphor layer is provided on the outer wall of the transparent plate opposite the glass dielectric. The coating to reduce the ignition voltage results in a disadvantage that the dielectric surface does not have a phosphorescent layer and as a result sacrifices some of the maximum luminous efficiency.

In US-A 6 097 155 a dielectric barrier discharge lamp of the type mentioned in the introduction is known. The lamp has a tubular discharge vessel, wherein at least two long electrodes similar to conductor tracks are arranged parallel to the longitudinal axis of the discharge vessel on the inner and / or outer walls of the discharge vessel. Even in this case, ignition-related problems arise when the lamp is not visible, for example when present inside the OA device.

(Detailed Description of the Invention)
It is an object of the present invention to provide a method for igniting and operating a dielectric barrier discharge lamp according to the preamble of claim 1 which results in a high luminous efficiency and improved ignition response of the lamp.

This object is achieved by the features of claim 1. Particularly preferred embodiments are presented in the dependent claims according to claim 1.

Another object of the present invention is to provide a circuit suitable for carrying out the method.

This object is achieved by the features of the independent claims for the circuit. Particularly preferred embodiments are thus presented in the dependent claims.

Also claimed is protection for lamps suitable for the method and for lighting systems consisting of lamps and circuits.

In the method according to the invention for igniting and operating a dielectric barrier discharge lamp with a long electrode, at least one long electrode is divided into two partial electrodes by a gap and the following steps are carried out in a lamp modified in this way. .

In the ignition step, an ignition voltage is applied between the two partial electrodes in such a way that an auxiliary discharge is ignited in the electrode gap region between the two partial electrodes.

In the next normal operation, the operating voltage is applied between the electrodes in such a way that the main discharge is combusted between the two electrodes.

The advantage of this method is that it facilitates the ignition of the main discharge, in particular by means of a pre-fired auxiliary discharge. As a result, in the ignition phase, the operating voltage does not need to be high even when the auxiliary discharge is turned off. As a result, when designing a ramp voltage generator that supplies an operating voltage, the additional cost needed to increase electrical strength can be avoided. Only the drive circuit for the electrode gap to ignite the auxiliary discharge needs to be designed to have a moderately high electrical strength to ensure reliable ignition. However, the voltage level required for ignition of the auxiliary discharge can be limited by relatively simple measures. The electrode gap is therefore preferably chosen to be smaller than the distance from the nearest electrode or smaller than the distance between the electrodes of opposite polarity, the main discharge being burned in normal operation between the electrodes. This ensures that the ignition voltage of the auxiliary discharge is lower than the ignition voltage of the main discharge without the aid of the auxiliary voltage. In addition, even at the end of the partial electrode limiting the electrode gap, the dielectric impediment can be completely eliminated (dielectrically uninterrupted auxiliary discharge), or only one end can be genetically disturbed (one end is genetically Disturbed secondary discharge). The dielectrically uninterrupted secondary discharge has the advantage of having a particularly low ignition voltage, even if more impurities are caused by the sputtering process in the two partial electrode end regions. It may therefore be desirable to bear in this connection a complete gap, but at least a partial electrode end, with one dielectric layer (both ends are dielectrically disturbed auxiliary discharges), thereby resulting in a relatively high ignition voltage for the auxiliary discharges. It is also desirable that the amount of power in the auxiliary discharge be much smaller than the main discharge. The drive circuit for this auxiliary discharge thus has a correspondingly smaller dimension and can therefore be manufactured at low cost.

Another advantage is that in addition to the gap in one electrode-even if there are multiple electrode gaps if necessary-no further deformation is required inside the discharge vessel of the lamp. This avoids the negative effects on the lamp luminous flux, for example known from US 5 006 758 cited above.

In normal operation the voltage value between the two partial electrodes is preferably chosen lower than the ignition voltage and / or the sustain voltage of the auxiliary discharge. Therefore, the auxiliary discharge is turned off in normal operation. In this case, the homogeneity of the main discharge and the lamp brightness is not influenced as a whole, and furthermore, there is an advantage that the auxiliary discharge driving circuit is in a no-voltage state during normal operation. In normal operation, it is particularly desirable that the voltage value between the two partial electrodes be selected sufficiently low to prevent the effects on the main discharge. In normal operation it has proved particularly desirable for the two partial electrodes to be at substantially the same potential.

In normal operation, an operating voltage is preferably applied between an electrode divided into two parts and a counter electrode thereof. As a result, the main discharge extends even between each partial electrode and the adjacent counter electrode. In this case, the electrode divided into two parts is advantageously used not only for ignition but also for generating a main discharge. That is, it operates like a normal electrode in normal operation.

The operating voltage is also preferably tuned to the pulsed effective power that contributes to the gas discharge, and the pulse rate and the inter-pulse speed of the voltage are selected such that the main discharge consists of a myriad of partial discharges. For further details see US-A 5 604 410 cited above. It has also been proved in this connection that the opposite electrode of the electrode divided into two parts and / or the electrode itself divided into two parts have means for localizing the partial discharge. In this case the electrode gap is preferably arranged between two means, ie between two partial discharges which burn during operation. In this way the original partial discharge pattern of the main discharge remains unchanged by the electrode gap. The means for locating the partial discharge is embodied by means of a nose shaped protrusion, for example, which are spaced apart from each other along at least one polarized electrode. For further details see US 6 060 828.

The circuit for carrying out the method described above has an ignition circuit for generating an auxiliary discharge ignition voltage and a lamp voltage generator designed to generate an operating voltage for main discharge. The ignition voltage is drawn at both terminals of the secondary side of the ignition transformer. The primary side of the ignition transformer is powered from a direct current voltage source by first means for applying a voltage. The first means is embodied, for example, as a controllable switch connected to one terminal of the primary side of the ignition transformer. The ignition circuit also has a second means for shorting the primary side of the ignition transformer. The second means is for example a controllable switch connected in parallel to the primary winding of the ignition transformer. As the ignition transformer, for example, a conventional coil transformer or a piezoelectric transformer is used.

In a full lighting system, the first terminal of the secondary side of the ignition transformer is connected with one partial electrode of the dielectric barrier discharge lamp. The second terminal on the secondary side and the first output of the ramp voltage generator are connected with the other partial electrode and the undivided electrode of the first polarity. Finally, the second output of the lamp voltage generator is connected with the electrode of the second polarity.

The long electrode of the dielectric barrier discharge lamp is embodied, for example, as an electrode track attached to the wall of the discharge vessel. The electrode track can be printed, for example, by conventional printing techniques (silkscreen printing, stencil printing). The electrode gap divides the relevant electrode track into two partial electrode tracks in the longitudinal direction.

The invention is further illustrated by the examples shown in the following figures.

(Short description of the drawing)
1 is a cross-sectional view of an electrode structure of a planar dielectric barrier discharge lamp,

2 is a simplified circuit diagram of a circuit for igniting and operating a dielectric barrier discharge lamp having the electrode structure according to FIG.

(Example)
1 shows a cross section of an electrode structure of a planar dielectric barrier discharge lamp. The electrode structure is designed to be operated by a unipolar voltage pulse and for this purpose has a plurality of anode tracks (A) and cathode tracks (K), the anode tracks and the cathode tracks being mounted on a base plate of a planar ramp (not shown). It is printed. In this case, one cathode track is always arranged between the two anode tracks. For clarity only one cross section is shown here with two anode tracks and one cathode track. The electrode tracks are covered by a thin glass layer (not shown) that acts as a dielectric barrier. Each cathode track K has projections V on both sides, which projection V is used as a means for locating a triangular partial discharge E which burns during operation. The anode track on the right side of FIG. 1 is divided into two partial anode tracks A and A 'by a gap L that interrupts the anode track. The length l of the electrode gap L is about 0.8 mm. Another anode track A is arranged to the left of the cathode track K, which consists of one part. The smallest distance d between the anode tracks A, A 'and each of the cathode tracks K closest to each other is about 6 mm. Depending on the size of the base plate, the cross section of this electrode structure is repeated several times and substantially covers the entire inner surface of the base plate. Typically, however, one anode track, or a small number of anode tracks with the above electrode gap is sufficient in the case of planar lamps that occupy a very large surface to support the ignition of the main discharge. The anode track and the cathode track are connected with a common supply lead (not shown) in the edge region of the planar lamp. The mode of operation of this electrode structure will be clearly described below in conjunction with the circuit of FIG. 2.

The circuit shown in simple form in FIG. 2 has an ignition transformer TR1. The primary circuit is powered from a direct current voltage source U1, which is connected to two terminals of the primary winding of the ignition transformer TR1 by a first field effect transistor FET M1. The second field effect transistor M2 is connected in parallel to the primary winding. The first terminal of the secondary winding of the ignition transformer TR1 is connected to the anode track A and the other terminal of the secondary winding is connected to the partial electrode track A 'or in some cases the partial electrode tracks. The circuit also has a ramp voltage generator U2, which is connected to the anode track A on the one hand and to the cathode track K on the other. The ramp voltage generator U2 supplies a suitable pulsed voltage train for pulsed power injection and can be implemented as known, for example, in US publication 6 323 600. Other controllable switches may be used instead of the FETs M1, M2.

The function will be described with reference to FIGS. 1 and 2 as follows. At the start of the ignition phase, the ramp voltage generator U2 supplies a pulsed operating voltage in advance, which operating voltage is applied between the anode track A and the cathode track K. The field effect transistor M1 is then driven in a pulsed manner by the control input unit X. In this manner, a high voltage is generated between the anode A and the partial electrode A 'on the secondary side of the ignition transformer TR1. The high voltage ignites the auxiliary discharge in the region of the gap L. In FIG. 1, the auxiliary discharge is not seen in FIG. The secondary discharge starts the main discharge consisting of the partial discharges E.

Then, starting the normal operation, the first field effect transistor M1 is controlled to a high resistance state. On the contrary, the second field effect transistor M2 is controlled by the control input unit Y in a conductive state, that is, a low resistance state, thereby shorting the primary side of the ignition transformer TR1. As a result, the two terminals on the secondary side of the ignition transformer TR1 and the anode track A and the partial electrode track A 'connected thereto are at the same potential. In this way, the operating voltage U2 is operated between the partial electrode track A 'and the cathode track K in normal operation. This can ensure that the partial discharge E is likewise combusted between the partial electrode track A 'and the closest cathode track K in normal operation. This has the advantage that the partial electrode track A 'is used not only for the ignition auxiliary discharge but also for the main discharge. Otherwise these areas may be undesirably dark during normal operation.

The present invention mainly describes the case of flat lamps in more detail, but is not limited to these lamp types. Rather, the present invention can also be used in dielectric barrier discharge lamps having a discharge tube of a different type than the planar discharge tube, in which case the desired effects of the planar lamp are not lost. Thus, the present invention can be used very simply in a tubular lamp having, for example, a tubular discharge tube, by having the anode track interrupted by the cathode track and the gap disposed radially opposite to each other on the inside and parallel to the longitudinal axis of the discharge tube. Basically the driving is done in the same way as in a flat lamp.

Claims (16)

Ignite and operate a dielectric barrier discharge lamp having long electrodes A, K, wherein at least one long electrode A, K is divided into two partial electrodes A, A 'by a gap L. As a way to make An ignition step of applying an ignition voltage between the two partial electrodes (A, A ') in such a manner that an auxiliary discharge is ignited in a gap (L) region between the two partial electrodes (A, A'); And A method of ignition and operation of a dielectric barrier discharge lamp comprising a normal operating step of applying an operating voltage between the electrodes (A, K) in such a way that a main discharge (E) is combusted between the electrodes (A, K). . The method of claim 1, In the normal operation step, the voltage value between the two partial electrodes (A, A ') is selected to be lower than the ignition voltage or the sustain voltage of the auxiliary discharge. The method according to claim 1 or 2, Ignition and operation of the dielectric barrier discharge lamp, characterized in that the voltage value between the two partial electrodes (A, A ') in the normal operation step is selected so as to prevent the influence on the main discharge (E). Way. The method according to claim 1 or 2, And in said normal operation step said two partial electrodes (A, A ') are maintained at substantially the same potential. The method according to claim 1 or 2, In the normal operation step, the operating voltage is applied between the electrodes A and A 'divided into the two parts and the counter electrode K thereof, so that the main discharge E is applied to each of the partial electrodes A and A. ') And the adjacent counter electrode (K) extending to the method of ignition and operation of the dielectric barrier discharge lamp. The method according to claim 1 or 2, The operating voltage is tuned to a pulsed effective power contributing to gas discharge, and the pulse period and the inter-pulse period of the voltage are selected such that the main discharge consists of a plurality of partial discharges (E). How to ignite and operate the lamp. The method of claim 6, The opposite electrode K of the electrode divided into two parts and / or the electrode itself divided into two parts has means V for positioning the partial discharge E of the main discharge. Method of ignition and operation of the discharge lamp. The method of claim 7, wherein Ignition of the dielectric barrier discharge lamp, characterized in that the electrode gap L is arranged between the two means V for locating the partial discharge, which is between two partial discharges E which are burned during operation. How it works. A circuit device for carrying out the method according to claim 1 or 2, comprising: An ignition transformer TR1 including a first terminal A and a second terminal A 'for drawing the ignition voltage on the secondary side, First means for applying a voltage to the primary side of said ignition transformer TR1, and An ignition circuit comprising second means for shorting the primary side of the ignition transformer TR1; And Lamp voltage generator U2-The lamp voltage generator U2 is designed to generate an operating voltage and has a first output and a second output, the first output being the secondary of the ignition transformer TR1. And a second output part connected to an electrode (K). The method of claim 9, Said first means being a controllable switch (M1) connected to one terminal of the primary side of said ignition transformer (TR1). The method of claim 9, And the second means is a controllable switch (M2) connected in parallel with the primary side of the ignition transformer (TR1). A dielectric barrier discharge lamp with long electrodes A, K, suitable for the method of ignition and operation according to claim 1, wherein At least one long electrode is divided into two partial electrodes (A, A ') by a gap (L), the electrode gap (L) being provided for auxiliary discharge. The method of claim 12, And the length (l) of the electrode gap (L) is smaller than the distance (d) from the nearest electrode (K). The method according to claim 12 or 13, The long electrodes are embodied as electrode tracks (A, A ', K) arranged on the wall of the discharge vessel. The method of claim 14, The electrode gap (L) divides the associated electrode track in the longitudinal direction into two partial electrode tracks (A, A '). 13. A lighting system comprising the circuit arrangement according to claim 9 and the dielectric barrier discharge lamp according to claim 12. The first terminal on the secondary side of the ignition transformer TR1 is connected to one partial electrode A ', and the second terminal on the secondary side and the first output of the lamp voltage generator U2 are the remaining partial electrodes A. And the undivided electrodes (A) of the first polarity, and the second output of the lamp voltage generator (U2) is connected to the electrodes (K) of the second polarity.

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